Process for enzymatic deinking of printed papers

ABSTRACT

The present invention provides a process for enzymatic deinking of office waste paper inclusive of xerographic and inkjet-printed paper printed with non impact and non dispersible ink using the cell free culture supernatant of  Vibrio alginolyticus  or immobilized cells of the same bacterium having the accession number NIO/DI/32 and deposited at ARS Patent Culture Collection, USA, under the Number NRRL-B-30638. Further, this invention relates to decolorization of office waste paper pulp within 72 h after contacting the said enzymes from the said bacterium in the pulp of 3-12% consistency in seawater. Decolorization is achieved by using extracellular enzymes produced by the bacterium NIO/DI/32 grown in nutrient broth supplemented with starch or Tween 80.

FIELD OF INVENTION

The present invention relates to process for enzymatic deinking of office waste paper inclusive of xerographic and inkjet-printed paper printed with non impact and non dispersible ink.

More particularly, it relates to a process for enzymatic deinking of office waste paper inclusive of xerographic and inkjet-printed paper printed with non impact and non dispersible ink using the cell free culture supernatant of Vibrio alginolyticus or immobilized cells of the same bacterium having the accession number NIO/DI/32 and deposited at ARS Patent Culture Collection,USA, under the Number NRRL-B-30638.

BACKGROUND OF THE INVENTION

Paper manufacturing is a major industry and a continuously growing one. Increased production of paper imposes a severe demand on plant raw material and thus harms the environment. Recycling of used paper is an alternative that can alleviate the stress that is exercised on the environment. The three major sources of raw material for such recycling are newsprint, photocopied paper and inkjet—printed papers. Recycling of paper requires the removal of the printing ink from the used paper, called deinking, so that the processed material is brighter. Printing on paper is accomplished by using two types of inks, the impact and the non-impact inks. In impact inks, used for newsprints, the ink does not fuse with the paper and is, therefore, easy to remove or disperse during the deinking, or recycling process. Such recycling is now well known and has been carried out for years. On the contrary, non-impact inks used in photocopying, ink-jet printing and laser printing results in the ink fusing with the paper and makes it non-dispersible, thus rendering the deinking process much more difficult (Jeffries, 1996, website “Bioenergy”). The toners used for photocopying generally contain iron oxide (about 55%), olefins (about 5%) and plastic or polymer (Website:http://www.eng-tips.com).

Various hydrolytic enzymes such as cellulase, lipase, amylase of bacterial or fungal origin, individually or in combination have been used for deinking of office waste paper.

(i) A reference may be made to a publication wherein, a method for deinking of xerographic and printed paper, collectively called office waste, includes applying deinking solution to the paper to be deinked, the deinking solution being composed of a cleaning solution and a surfactant, abrading the paper to remove the ink from paper, and washing the paper to remove the deinking solution from the paper (U.S. Pat. No. 6,022,423 dtd Feb. 8, 2000). However, this patent involves using a special device for deinking of whole sheets and cannot be used on pulp.

(ii) A reference may be made to a publication wherein, a mono component cellulase is used for removal of ink and toners from printed paper (U.S. Pat. No. 5,525,193). The technique of isolating mono component cellulase from microorganisms by various purifications, chromatographic steps which is time consuming and expensive.

(iii) A reference may be made to a publication wherein, endogluconases and hemicellulases from several fungi are used effectively for deinking of xerox and laser-printed paper (Gubitz et al., 1998). However, the pulp needs to be treated with surfactants and washed to remove the floating ink particles.

(iv) A reference may be made to a publication, wherein deinking of laser printed or xerographic paper is done using enzyme containing a resistant binder. Enzyme is added in the specified form to improve speck removal (Patent No. GB 2304741 dated Mar. 26, 1997). As with the above references, the technology to remove the ink by floatation remains a problem.

(v) A reference may be made to a publication, wherein deinking of office waste paper is carried out by contacting the pulp with a deinking agent containing enzymes cellulase, preferably active at pH 4 to 8. The treated paper is used in the production of newsprint and high quality paper (Patent No. EP 717144 dated Jun. 19, 1996). As with the above references, the technology to remove the ink by floatation remains a problem.

(vi) A reference may be made to a publication, wherein deinking of waste paper is achieved by incubating the paper pulp with cellulase at 40° C. for 1 hour under pressure. Following dissociation of ink particles, the resulting washed pulp is brighter (Patent No. JP 06346390 dated Dec. 20, 1994). The technology for incubation under pressure and high temperature is an expensive process.

(vii) A reference may be made to a publication, wherein deinking is achieved by using lipase to remove ink from used paper. The procedure is carried out under neutral or alkaline conditions which produces regenerated pulp having enhanced brightness (Patent No. JP 2160984 dated Jun. 20, 1990). The ink particles are removed by washing and floatation.

(viii) A reference may be made to a publication, wherein deinking of waste paper is done by using the yeast Hansenula polymorpha, which degrades the ink-based resin (Patent No. KR 9303705 dated may 8, 1993). However, the ink floats on the surface and the pulp has to be extensively washed to remove the detached ink.

(ix) A reference may be made to a publication, wherein decolorization of Indian ink is achieved by using thermostable alkaline cellulase from a Bacilus sp (Patent number JP10313859). However, this process is very specific to Indian ink.

(x) A reference may be made to a patent filed, wherein decolorization of office waste is achieved by inoculating the paper pulp with the bacterium Vibrio alginolyticum (US Patent application Number 20030178162). However, handling the live bacterium is a big disadvantage in this process and may not be acceptable to many.

OBJECTS OF THE INVENTION

The main object of the present invention is to provide a process for enzymatic deinking of office waste paper inclusive of xerographic and inkjet-printed paper printed with non impact and non dispersible ink.

Another object of the present invention is to provide a process for enzymatic deinking of office waste paper inclusive of xerographic and inkjet-printed paper printed with non impact and non dispersible ink using the cell free culture supernatant of Vibrio alginolyticus or immobilized cells of the same bacterium having the accession number NIO/DI/32 and deposited at ARS Patent Culture Collection, USA, under the Number NRRL-B-30638.

SUMMARY OF THE INVENTION

The present invention relates to a process for enzymatic deinking of office waste paper inclusive of xerographic and inkjet-printed paper printed with non impact and non dispersible ink using the cell free culture supernatant of Vibrio alginolyticus or immobilized cells of the same bacterium having the accession number NIO/DI/32 and deposited at ARS Patent Culture Collection, USA, under the Number NRRL-B-30638. Further, this invention also relates to decolorization of office waste paper pulp within 72 h after contacting the said enzymes from the said bacterium in the pulp of 3-12% consistency in seawater. Decolorization is achieved by using extracellular enzymes produced by the bacterium NIO/DI/32 grown in nutrient broth supplemented with starch or Tween 80.

DETAILED DESCRIPTION OF THE INVENTION

Deinking of paper is a limiting factor in recycling of paper. Newsprint and office waste paper is generally deinked using chemicals which go into the effluent and cause pollution of the water bodies. The newsprint or offset printing is done using dispersible or non-impact ink whereas laser, xerographic and ink-jet printer ink does not disperse and is also called impact ink. There are several patents describing various methods of deinking by using hydrolytic enzymes such as cellulase, hemicellulase and lipase of microbial origin which release toner particles from fibers. However, enzyme action is affected by the paper constituents in the deinking condition. The chemically pulped fibers are more susceptible than mechanically pulped fibers. Office waste paper is high in laser and toner content and the technology for taking the toner particles out is not very good at the moment (Jefferies, 2002). We report here a process for deinking of office waste paper comprising xerographic and ink-jet printed paper by cell free culture filtrate of a bacterium isolated from marine sediment of an estuary in Goa, India. The salinity of the water at the time of isolation was around 15 parts per thousand which is roughly equivalent to half-strength sea water.

The organism given in the present invention is Vibrio alginolyticus, a'gram-negative, coccoid bacterium isolated from coastal marine sediment and given the accession number NIO/DI/32 and is deposited in ARS patent culture collection center having accession number NRRL-B-30638. The said bacterium is grown in nutrient broth containing beef extract, peptic digest of animal tissue, prepared with sea water with salinity diluted to 50% and having a pH of at least 7.5 and supplemented with 1% starch or 1% Tween-80 solution or both. The bacterium when grown in nutrient agar medium appears as circular colonies off-white in color, having 2 mm diameter in the beginning and growing to a size of 5 mm within 3-4 days. The bacterium produces esterase/lipase and amylase in the presence of Tween-80 and starch respectively. It is fermentative and catalase-negative bacterium. The bacterium is grown at room temperature (30° C.) for about 4 days, the culture supernatant is collected by centrifugation under sterile conditions. Xerographic, ink-jet printed paper and other papers printed with impact ink are pulped by soaking in hot water for a minimum of 2 hrs, macerated in a domestic mixer with surfactant such as Tween-80. An example for the process for deinking involves suspending such a pulp at least at 3-12% consistency in seawater with salinity diluted to 50%, incubating with cell-free culture supernatant of the said bacterium. The treated pulp is incubated at room temperature or 37° C. for a minimum of 2-3 days to get completely decolorized pulp without traces of ink in the supernatant. The pulp is diluted, aerated from bottom to remove free contaminating particles and salts. Soap solution is added at 1% concentration for flotation of any residual ink particles. The pulp is filtered over a Buchner funnel under suction, pressed with flat stainless steel plates to make the pulp sheet uniform in thickness. The radiance of the resultant sheet is read from 412 to 684 nm and the radiance expressed in Lux units (Lu). One LU is equivalent to W/cm²/nm/Sr. The ratio of radiance between enzymatically deinked and recycled paper purchased from the market (hereafter called the reference paper) is taken as a measure of brightness.

Most of the methods used for enzymatic deinking release ink particles from the fibers and they need to be subsequently washed off from the pulp. In the process described in the present invention, this problem does not arise as the ink and toner particles are totally decolorized. The method is very cost effective as the only step involved is raising the bacterial inoculum in any conventional nutrient broth containing assimilable carbon and nitrogen source and supplemented with starch or Tween-80. A comparative statement given in Table 1 explains the novelty of our. invention in comparison with prior art known in this field.

TABLE 1 Comparative statement Type of Reference paper or (Prior art) ink Source of deinking agent Remarks Patent Impact ink Chemical & a surfactant, abrading the Not practical on a US6022423 and office paper and washing the deinked paper large scale waste using a special device to put a whole sheet US5525193 Toner, Monocomponent cellulase purified from The ink particles impact ink cellulolytic enzymes of various get freed from the from mixed microorganisms or genetically pulp, but they need office waste engineered organism which produces to be removed by only monocomponent cellulase mechanical methods such as floatation and washing. Gubitz et al. Xerox and Endogluconases and hemicellulases The ink particles 1998 laser- from fungi get freed from the printed pulp, but they need paper to be removed by mechanical methods such as floatation and washing. GB2304741 Laser- Enzyme containing a resistant binder The ink floats on printed or the surface and the xerographic pulp has to be paper extensively washed Patent Office Cellulase The ink floats on EP 717144 waste paper the surface and the pulp has to be extensively washed JP06346390 Office Contacting with cellulase at 40° C. for 1 h Enzyme high waste paper under pressure temperature and pressure will make the cost of technology not very practical. JP2160984 Office Contacting pulp with lipase enzyme The ink floats on waste paper under neutral or alkaline conditions the surface and the pulp has to be extensively washed. KR9303705 Office Contacting pulp with the culture of the The ink floats on waste paper yeast Hansenula polymorpha which the surface and the degrades the ink-based resin. pulp has to be extensively washed JP10313859 For Thermostable alkaline cellulase from a Recommen-ded for decolorization bacterium surfactant of Indian composition, as a ink fiber treatment agent and as an Indian ink decolorization agent. US Patent For Live bacterial culture of Vibrio Recommended for Application deinking of alginolyticus deinking of Xerox No. office waste and ink jet-printed 20030178162 paper pulp. Using live bacterium may not be acceptable to many. Present For Xerox Direct contact of the pulp slurry with the No enzyme, invention and inkjet- cell free culture supernatant of the purification, no printed bacterium NIO/DI/32 for 48-72 h at temp-erature or pH paper pulp room temperature to get complete adjustment, the decolorization of the pulp and clear pulp and the water waste water. are clear and washing is only optional.

Accordingly the present invention provides a process for enzymatic deinking of printed papers inclusive of xerographic and inkjet-printed paper printed with non impact and non dispersible ink comprising:

-   -   a) growing the bacterial isolate Vibrio alginolyticus having         accession number NIO/DI/32, the culture being deposited at ARS         Patent Culture Collection under NRRL Number NRRL-B-30638, in a         novel medium at a temperature ranging from 27° C. to 37° C. for         3-4 days;     -   b) removing the bacterial cells by centrifugation under sterile         condition to obtain cell free culture supernatant;     -   c) incubating the xerox or inkjet-printed paper pulp diluted to         3-12% consistency in sea water with salinity diluted to 50% with         the resulting cell free culture supernatant obtained from         step (b) at 20% concentration for at least 72 hours at room temp         followed by diluting the pulp ten fold in water to obtain         completely decolorized pulp without traces of ink in the         supernatant;     -   d) filtering the resulting pulp obtained from step (c) under         suction to get the desired deinked paper.

In an embodiment of the present invention, the medium is prepared by dissolving nutrient broth contains beef extract, peptic digest of animal tissue in sea water with salinity diluted to 50% and supplemented with tween 60 or 1% starch or both.

In another embodiment of the present invention, the bacterium is grown for a minimum of 4 days in nutrient broth containing beef extract, peptic digest of animal tissue in sea water with salinity diluted to 50% and supplemented with tween 60 or 1% starch or both.

In yet another embodiment of the present invention, the sodium chloride at a minimum concentration of 1.5% can be used in the place of sea water for growing the bacterium.

In yet another embodiment of the present invention, cell free supernatant contains the extracellular enzymes such as esterase, lipase and amylase etc, used for deinking of papers.

In still another embodiment of the present invention, the xerographic or inkjet-printed paper is soaked in hot water for 1-2 hours after addition of 1% surfactant followed by macerating it to pulp using any domestic mixer.

In still another embodiment of the present invention, the pulp sheet is pressed to make it uniform and dried at about 60° C. for a minimum of 4-5 hours.

In still another embodiment of the present invention, the radiance of the resultant sheet is read from 412 to 684 nm and the radiance expressed as Lux units (LU). One LU is equivalent to μW/cm²/nm/Sr.

In still another embodiment of the present. invention, the pulp sheet made out of recycled paper available in the market is used as a reference.

In still another embodiment of the present invention, the same batch of cell free culture supernatant can be effectively used for two-three cycles of deinking of xerox paper/inkjet-printed paper pulp.

In still another embodiment of the present invention, the lyophilized culture supernatant can also be effectively used for deinking of the said pulp.

In still another embodiment of the present invention, bacteria immobilized in sodium alginate beads can also be used for deinking the xerox paper/inkjet printed paper pulp to get completely bleached pulp within 48-72 hours.

The following examples are given by way of illustration of the present invention and should not be construed to limit the scope of present invention.

EXAMPLE 1

The bacterial isolate Vibrio alginolyticus NIO/DI/32 was isolated from the coastal esturine sediment, Dona Paula, Goa, India in nutrient agar medium containing beef extract and peptic digest of animal tissue and agar in sea water with its salinity diluted to 50%. The culture was maintained in the slants of nutrient agar medium for all further experiments.

The said bacterium is grown in nutrient broth containing beef extract, peptic digest of animal tissue in sea water with its salinity diluted to 50%. Besides, the medium is amended either with starch or Tween-80 or a both together used at 1% concentration. The bacterium is grown at room temperature (30° C.) for about 4 days, the bacterial cells are removed by centrifugation and the cell-free culture supernatant is used for deinking purposes. Xerographic paper printed with impact ink from HP or Epson or any other printer are pulped by soaking in hot water for a minimum of 2 hrs, macerated in a conventional domestic mixer with surfactant such as Tween 80. An example for the process for deinking involves suspending such a pulp at 3, 6 and 9% consistency (g wet pulp in 100 ml of water) incubating with 50 ml of cell free culture supernatant prepared as described above and incubating at room temperature for a minimum of 3 days to get completely bleached pulp with the ink totally disappearing from the supernatant water. The pulp is diluted, aerated from bottom to remove free contaminating particles. Soap solution is added at 1% concentration for flotation of any residual ink particles. The pulp is filtered over a Buchner funnel under suction, pressed with flat stainless steel plates to make the pulp sheet uniform in thickness. The radiance of the resultant sheet is read from 412 to 684 nm and the radiance expressed in Lux units (Lu). One LU is equivalent to μW/cm² /nM/Sr. The ratio of reflectance between recycled paper available in any stationery shop (reference paper) and biologically deinked paper is taken as a measure of brightness. The reflectance of untreated pulp is the negative control.

Accordingly, FIG. 1A-1C show the reflectance of ink jet-printed paper pulp (untreated) is lower than that of reference paper pulp (recycled paper purchased from market). The printed paper pulp treated with culture supernatant containing starch, Tween-80 or both showed higher radiance than the untreated pulp. This brightness was achieved 3 days after incubation with the culture supernatant. Accordingly FIG. 1A, 1B and 1C show that treatment with culture filtrate containing the fatty acid ester Tween 80 yielded highest brightness. Treatment with culture filtrates of starch or Tween 80-grown cultures or both together increased the brightness much more than the reference paper pulp (the target brightness). Ratio of radiance of untreated printed paper pulp to recycled paper and ratio of radiance of enzymatically deinked paper to that of recycled reference paper pulp (Table 1) showed that, pulp at 6% concentration treated with culture supernatant containing Tween 80 showed the maximum brightness.

TABLE 1 Ratio of reflectance achieved using various treatments. Reflectance ratio % increase in Treatment* (Lux Units)*** reflectance 3% Pulp Untreated pulp (negative control) 0.54 Pulp treated with CF containing 1.04 48 Starch** Pulp treated with CF containing 1.39 61 Tween 80** Pulp treated with CF containing 1.29 58 Starch + Tween 80 6% Pulp Untreated pulp (negative control) 0.57 Pulp treated with CF containing 1.03 45 Starch Pulp treated with CF containing 1.24 64 Tween 80 9% Pulp Untreated pulp (negative control) 0.68 Pulp treated with CF containing 0.88 23 Starch Pulp treated with CF containing 1.05 35 Tween 80 *Culture filtrate (CF) of the bacterium NIO/D!/32 grown in nutrient medium for 4 days was added to paper pulp of various concentrations (W/V). **Starch or Tween 80 were added to the medium at 1% concentration. ***Reflectance ratio was calculated by dividing average reflectance of untreated or treated pulp at different wave lengths by average reflectance of reference (target) paper pulp.

EXAMPLE 2

The aim of the present experiment was to compare deinking of pulp using the bacterial culture supernatants containing starch and Tween 80 at room temperature and at 37° C.

The printed pulp at 3% consistency was incubated with bacterial culture supernatant containing starch or Tween 80 for 72 hours at 37° C. At the end of the incubation period, the slurry was filtered, washed and dried as described in the Example 1. The reflectance was measured as detailed above.

Accordingly, FIGS. 2A and 2B show that no significant improvement in brightness occurred at 37° C. Table 2 shows the comparative average reflectance ratios in various treatments. The results indicate that effective deinking can be achieved by treating at room temperature and thereby reducing energy utilization.

TABLE 2 Ratio of reflectance achieved using various treatments Treatment* Reflectance ratio % increase in (3% pulp) (Lux Units)*** reflectance Untreated pulp (negative control) 0.54 at RT Pulp treated with CF containing 1.04 48 Starch** incubated at RT Pulp treated with CF containing 1.39 61 Tween 80** incubated at RT Pulp treated with CF containing 1.29 58 Starch + Tween 80 incubated at RT Untreated (negative control) 0.54 incubated at 37° C. Pulp treated with CF containing 1.19 54 Starch** incubated at 37° C. Pulp treated with CF containing 1.14 53 Tween 80** incubated at 37° C. Pulp treated with CF containing 1.09 51 Starch + Tween 80 Incubated at 37° C. *Culture filtrate (CF) of the bacterium NIO/D!/32 grown in nutrient medium for 4 days was added to paper pulp of various concentrations (W/V). **Starch or Tween 80 were added to the medium at 1% concentration. ***Reflectance ratio was calculated by dividing average reflectance of untreated or treated pulp at different wave lengths by average reflectance of reference (target) paper pulp.

EXAMPLE 3

In order to avoid direct contact with bacterial inoculum, the ability of the immobilized bacterial isolate NIO/DI/32 to deink inkjet printed paper was carried out as follows:

Bacterial cells were immobilized in sodium alginate. Briefly, this involved mixing 8 ml of cells (containing 10⁸ cell ml⁻¹) with 25 ml of 2% alginic acid (Sigma Chemicals, USA). The beads were prepared in 0.2 M calcium chloride solution and were cured for overnight. The same batch of immobilized bacterial cells were used in two cycles to achieve deinking. The other procedures used were the same as described in the Example 1.

Accordingly, FIG. 3 shows radiance of decolorized paper pulp after 72 hours incubation with two cycles of immobilized cells. The average reflectance ratios in these two cycles of immobilized cells are shown in Table 3. It can be concluded that immobilized cells were as effective as the free bacterial cells in deinking. The repeated use of immobilized cells is an added advantage.

TABLE 3 Ratio of reflectance achieved using various treatments. Treatment* Reflectance ratio % increase in (3% pulp) (Lux Units)*** reflectance Untreated (negative control) at 0.54 RT Free cells* 1.13 52 Immobilized cells, cycle I** 1.24 56 Immobilized cells, cycle II 1.09 50 *Immobilized cells/free cells of the bacterium NIO/D!/32 grown in nutrient medium for 4 days were added to paper pulp of various concentrations (W/V). **Same batch of Immobilized cells were used in two cycles. ***Reflectance ratio was calculated by dividing average reflectance of untreated or treated pulp at different wave lengths by average reflectance of reference (target) paper pulp.

EXAMPLE 4

The deinking of inkjet-printed paper was carried out using heat-killed bacterial cells and heat-inactivated culture supernatants (containing starch or Tween 80). For this purpose the bacterial cells and the culture supernatants were autoclaved at 121° C. for 15 minutes at 15 lb.

The preparation of pulp, inoculum and experimental set up and incubation were same as in the previous examples.

Accordingly, FIG. 4 shows that by day 3 no deinking could be achieved by using killed bacterial cells and heat-inactivated culture supernatants indicating that the active principle responsible for deinking is heat sensitive.

EXAMPLE 5

The effect of storage of culture supernatant is one of the important criteria for its effective use. Therefore, the crude culture supernatant stored for 2 days at room temperature was used for deinking of the pulp. For comparison, the fresh culture filtrate was used for deinking the pulp. The procedure for deinking was the same as described in examples 1-4.

Accordingly, FIGS. 5A and 5B show that the stored supernatants lost its efficiency as compared to the fresh culture filtrate in deinking, indicating that the active principle involved in deinking is unstable when stored at room temperature.

We also compared the efficiency of the freeze-dried culture filtrate on deinking. Accordingly, Table 4 shows that the freeze-dried culture filtrate from medium containing starch or Tween 80 could effectively deink the pulp.

TABLE 4 Reflectance ratio of the pulp treated with freeze-dried culture supernatant. Treatment* Reflectance ratio % increase in (3% pulp) (Lux Units)*** reflectance Untreated (negative control) at 0.54 RT Pulp treated with freeze-dried CF 1.25 57 containing starch Pulp treated with freeze-dried CF 1.25 57 containing Tween 80

The freeze-dried culture filtrate (CF) was thawed and diluted to the original volume with 50% diluted sea water and incubated with pulp. The negative control was incubated with 50% diluted sea water.

EXAMPLE 6

The active principles involved in deinking of the pulp using culture supernatant of media containing starch or Tween 80 were investigated. Accordingly, amylase and lipase activities were measured in these supernatants. Amylase activity was measured using 1% starch, iodine and potassium iodide (Medda and Chandra 1980). Lipase activity was measured using model substrate 4-methylumbelliferyle-butyrate (Sigma Chemicals, USA). The fluorescent MUF product released is measured at excitation and emission wave length of 364 and 445 nm respectively (Hoppe H-G. 1993). The use of Tween 80 in the medium will induce esterase as well as lipase activity (Gupta et al. 2003).

Accordingly the 5-day old culture filtrate containing starch and Tween 80 showed 49 and 33 U ml⁻¹ activity respectively. These were the minimum concentrations required for effective deinking because diluting the enzyme solutions did not result in effective deinking. FIG. 6 shows the untreated control and enzyme treated pulp.

ADVANTAGES

The main advantages of the present invention are:

-   -   1. Cell free supernatant can be reused for deinkinking of office         waste paper inclusive of xerographic and inkjet-printed paper         printed with non impact and non dispersible ink.     -   2. There is no need of enzyme purification in the present         process.     -   3. No temperature and pH adjustment is required. 

1. A process for enzymatic deinking of printed papers inclusive of xerographic and inkjet- printed paper printed with non impact and non dispersible ink comprising: a) growing the bacterial isolate Vibrio alginolyticus having accession number NIO/DI/32, the culture being deposited at ARS Patent Culture Collection under NRRL Number NRRL-B-30638, in a novel medium at a temperature ranging from 27° C. to 37° C. for 3-4 days; b) removing the bacterial cells by centrifugation under sterile condition to obtain cell free culture supernatant; c) incubating the xerox or inkjet-printed paper pulp diluted to 3-12% consistency in sea water with salinity diluted to 50% with the resulting cell free culture supernatant obtained from step (b) at 20% concentration for at least 72 hours at room temp followed by diluting the pulp ten fold in water to obtain completely decolorized pulp without traces of ink in the supernatant; d) filtering the resulting pulp obtained from step (c) under suction to get the desired deinked paper.
 2. A process according to claim 1, wherein the strain used has the following characteristics: a) it is a gram negative bacterium; b) it is a coccoid bacterium isolated from the coastal marine sediments of Dona Paula, Goa.
 3. A process according to claim 1, wherein the said novel medium is prepared by dissolving the nutrient broth in sea water with salinity diluted to 50% and supplemented with tween 60 or 1% starch or both.
 4. A process according to claim 1, wherein sodium chloride at a minimum concentration of 1.5% can be used in the place of sea water for growing the said bacterium.
 5. A process according to claim 1, wherein the xerographic or inkjet-printed paper is soaked in hot water for 1-2 hours after addition of 1% surfactant followed by macerating the pulp.
 6. A process according to claim 1, wherein the pulp sheet is pressed to make it uniform followed by drying at temperature ranging from 25° C. to 70° C. for a period of 4-5 hours.
 7. A process according to claim 1, wherein the same batch of cell free culture supernatant can be effectively used for two-three cycles of deinking of xerox paper/inkjet-printed paper pulp.
 8. A process according to claim 1, wherein the lyophilized culture supernatant can also be effectively used for deinking of the said pulp.
 9. A process according to claim 1, wherein bacteria immobilized in sodium alginate beads can also be used for deinking the xerox paper/inkjet printed paper pulp to get completely bleached pulp within 48-72 hours. 